Deployment system for multi-node applications

ABSTRACT

A deployment system provides the ability to deploy a multi-node distributed application, such as a cloud computing platform application, which has a plurality of interconnected nodes performing specialized jobs. The deployment system includes a deployment director that provisions an infrastructure that includes one or more virtual machines (VMs) for hosting the plurality of nodes of the cloud computing platform application. The deployment director distributes a plurality of jobs (e.g., application packages and configurations) to deployment agents executing on the provisioned VMs, based on a mapping in the deployment manifest between the infrastructure and the plurality of specialized jobs to be performed by the cloud computing platform application. The deployment agents apply the jobs to their respective VM (e.g., launching applications), thereby deploying the cloud computing platform application.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit and priority of U.S. provisional patent application Ser. No. 61/474,669, filed on Apr. 12, 2011, and entitled “DEPLOYMENT FRAMEWORK FOR CLOUD PLATFORM ARCHITECTURE,” which is hereby incorporated by reference. The present application is related to the patent application entitled “Release Management System for a Multi-Node Application” Ser. No. 13/428,121, and the patent application entitled “Release Lifecycle Management System for a Multi-Node Application” Ser. No. 13/428,125, which are assigned to the assignee of this application and have been filed on the same day as this application.

BACKGROUND

“Platform-as-a-Service” (also commonly referred to as “PaaS”) generally describes a suite of technologies provided by a service provider as an integrated solution that enables a web developer (or any other application developer) to build, deploy and manage the life cycle of a web application (or any other type of networked application). One primary component of PaaS is a “cloud-computing platform” which is a network (e.g., Internet, etc.) infrastructure run and maintained by the service provider upon which developed web applications may be deployed. By providing the hardware resources and software layers required to robustly run a web application, the cloud computing platform enables developers to focus on the development of the web application, itself, and leave the logistics of scalability and other computing and storage resource requirements (e.g., data storage, database access, processing power, facilities, power and bandwidth, etc.) to the cloud computing platform (e.g., at a cost charged by the service provider). A service provider may additionally provide a plug-in component to a traditional IDE (i.e., integrated development environment) that assists a developer who creates web applications using the IDE to properly structure, develop and test such applications in a manner that is compatible with the service provider's cloud computing platform. Once the developer completes a web application using the IDE, the plug-in component assists the developer in deploying the web application into the cloud computing platform.

However, due to complexities in providing flexible and scalable cloud computing platforms, PaaS is offered by few service providers. Current implementations of cloud computing platforms use multiple components (e.g., cloud controller, health manager, service provisioner, router, and application execution agents) that perform different roles and coordinate amongst each other to provide cloud computing services. To deploy such a cloud computing platform, a system administrator must build, configure, deploy, and maintain each of the components (e.g., cloud controller, health manager, service provisioner, router, and application execution agents). While deployment may be performed manually when installing all components on a single system (e.g., laptop, server), the deployment process becomes challenging when the components are installed across a plurality of networked systems because, in such installations, each system must be provisioned with specific computing resources, set up with a particular networking configuration, and have a different software application installed with dependent libraries and/or runtimes to perform the system's assigned role within the cloud computing platform. Additionally, updating any of the components (e.g., security patch for a library or operating system) requires a system administrator to have to modify operations for other components in the cloud computing platform. For example, when one of the components needs to be updated, a system administrator may have to suspend operations of other components currently connected to the component, or, in another example, update settings of other components to correctly connect to the updated component. Accordingly, the deployment process for a multi-node application such as a cloud computing platform may be too complex and time-consuming for a system administrator to manage.

SUMMARY

One or more embodiments of the present invention provide a deployment system for a multi-node distributed application (e.g., a cloud computing platform) having any number of nodes that perform specialized roles, as well as any dependent software and/or networking, storage, and service configurations utilized for each specialized role. Instances of the deployment system may be implemented on top of a hardware infrastructure that allows for dynamic provisioning of computing resources, such as a virtualized infrastructure. The deployment system includes an automation framework that utilizes codified deployment manifests to automatically provision infrastructure (e.g., virtual machines), as well as install and configure application packages needed for each specialized role. The codified deployment manifests simplify the deployment process for a complex multi-node application having varying requirements and enables repeatable and predictable deployments.

A method for deploying an application having a plurality of functional components that are executed on a plurality of different nodes, according to an embodiment, includes receiving, by a deployment module, a specification for the application. The specification specifies (i) a number of instances of each functional component of the application that is to be deployed, and (ii) hardware properties that would be required by any node executing any one of the functional components. The method includes requesting a virtual infrastructure platform to launch a plurality of virtual machines (VMs) that is sufficient to execute each instance of a functional component in a separate VM. Each of the VMs (i) is configured to support hardware properties required by at least one of the functional components, and (ii) includes an agent component configured to communicate with the deployment module. The method further includes directing each of the agent components in each of the VMs to install code in the VM that implements one of the functional components that is compatible with the hardware properties of the VM, thereby causing the VM to execute as one of the instances of the functional components of the application.

A non-transitory computer-readable storage medium comprises instructions that, when executed in a computing device, deploy an application having a plurality of functional components that are executed on a plurality of different nodes. The non-transitory computer-readable storage medium include, according to an embodiment, instructions for performing the step of receiving, by a deployment module, a specification for the application, wherein the specification specifies (i) a number of instances of each functional component of the application that is to be deployed, and (ii) hardware properties that would be required by any node executing any one of the functional components. The instructions further perform the steps of requesting a virtual infrastructure platform to launch a plurality of virtual machines (VMs) that is sufficient to execute each instance of a functional component in a separate VM. Each of the VMs (i) is configured to support hardware properties required by at least one of the functional components, and (ii) includes an agent component configured to communicate with the deployment module. The instructions further perform the steps of directing each of the agent components in each of the VMs to install code in the VM that implements one of the functional components that is compatible with the hardware properties of the VM, thereby causing the VM to execute as one of the instances of the functional components of the application.

A computer system for deploying an application having a plurality of functional components that are executed on a plurality of different nodes, includes, according to an embodiment, a system memory and a processor programmed to carry out the step of receiving, by a deployment module, a specification for the application. The specification specifies (i) a number of instances of each functional component of the application that is to be deployed, and (ii) hardware properties that would be required by any node executing any one of the functional components. The processor is programmed to carry out the step of requesting a virtual infrastructure platform to launch a plurality of virtual machines (VMs) that is sufficient to execute each instance of a functional component in a separate VM, wherein each of the VMs (i) is configured to support hardware properties required by at least one of the functional components, and (ii) includes an agent component configured to communicate with the deployment module. The processor is further programmed to carry out the step of directing each of the agent components in each of the VMs to install code in the VM that implements one of the functional components that is compatible with the hardware properties of the VM, thereby causing the VM to execute as one of the instances of the functional components of the application.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts a generalized schematic diagram of a multi-node distributed application.

FIG. 2 depicts one example of the multi-node distributed application of FIG. 1, namely, a cloud computing platform application.

FIG. 3 depicts one embodiment of a deployment system for a multi-node distributed application.

FIG. 4 depicts one embodiment of a deployment director and agents of a deployment system.

FIG. 5 depicts a flow diagram for deploying a cloud computing platform application by a deployment director.

FIG. 6 depicts the deployment system of FIG. 4 after deployment of a cloud computing platform application.

DETAILED DESCRIPTION

FIG. 1 depicts a generalized schematic diagram of a multi-node distributed application 100. Multi-node application 100 includes a plurality of nodes 102 (e.g., front and back end jobs) in communication via a message bus 104 to provide application services to a user 106. Each node 102 executes as an instance of a functional component and includes component software applications and/or libraries to perform one or more specialized tasks of the functional component within multi-node application 100. As described above, set-up and deployment of multi-node application 100 may be complex. For example, as each of the plurality of nodes 102 may serve different roles within multi-node application 100, nodes 102 may be on different networks, be connected to multiple dependent services 108, use different component software applications, have different resource requirements, and so forth.

FIG. 2 depicts a cloud computing platform application 200, which may be one example of a multi-node application 100, which dynamically provides cloud computing services to be utilized to host web applications 220. One example of cloud computing platform application 200 is described further in U.S. patent application Ser. No. 12/767,010, filed Apr. 26, 2010, and entitled “Cloud Platform Architecture,” which is hereby incorporated by reference in its entirety. Cloud computing platform application 200 includes specialized functional components, such as a cloud controller 202, a router 204, application execution agents 206, a health manager 208, a service provisioner 210, services 212, and a message bus 214. These functional components operate in a coordinated manner to provide cloud computing services, such as a relational database services (e.g., MySQL, etc.), CRM (customer relationship management) services, web services, application server services (e.g., JBoss, Rails, etc.), monitoring services, background task schedulers, logging services, messaging services, memory object caching service, and any other suitable software services, that may be accessed by web applications 220.

In one embodiment, cloud controller 202 orchestrates a deployment process for web applications 220 submitted by a developer 250. Cloud controller 202 interacts with other functional components of cloud computing platform application 200 to bind services required by submitted web applications 220 and package web applications for transmission to application execution agents 206 for deployment. Health manager 208 tracks and maintains the “health” of cloud computing platform application 200 by monitoring messages broadcast on message bus 214 by other functional components of cloud computing platform application 200. Web applications 220 access a set of services 212 provided by cloud computing platform application 200, such as a relational database service (e.g., MySQL, etc.), monitoring service, background task scheduler, logging service, messaging service, memory object caching service and the like. A service provisioner 210 serves as a communications intermediary between services 212 and other functional components of cloud computing platform application 200 (e.g., cloud controller 202, health manager 208, router 204, etc.) and assists with the task of provisioning or binding such available services to web applications 220 during a web application deployment process. Message bus 214 provides a common interface through which functional components of cloud computing platform application 200, such as, service provisioner 210, cloud controller 202, health manager 208, router 204 and application execution agents 206, can communicate and receive notifications.

Once cloud controller 202 successfully orchestrates the deployment of web application 220 in one or more application execution agents 206, an end user 106 can access web application 220, for example, through a web browser or any other appropriate client application residing on a computer laptop or, generally, any computing device. Router 204 receives the web browser's access request (e.g., a uniform resource locator or URL) and routes the request to the corresponding system which hosts web application 220.

As described, each component has a separate role within cloud computing platform application 200 with separate software application and library dependencies (e.g., MySQL, Redis, MongoDB, Apache) and is specially built, configured, deployed, and maintained for cloud computing platform application 200 to function as a whole. Further, since each component is typically run in one or more virtual machines (VMs), each VM is also specially provisioned, configured, deployed, and maintained by a system administrator. As such, cloud computing platform application 200, in which web applications 220 are deployed, itself has a deployment procedure that is cumbersome and complex. Accordingly, embodiments provide a deployment technique for cloud computing platform application that uses an automation framework and tooling for simplified, automatic, and repeatable deployments.

FIG. 3 depicts one embodiment of a multi-node application platform 300 having a deployment system 306 for deploying a multi-node distributed application. For example, a system administrator 302 may utilize multi-node application platform 300 to deploy cloud computing platform application 200 of FIG. 2, in which web applications 220 may be deployed.

In one embodiment, system administrator 302 instructs deployment system 306 by issuing one or more commands through an administrative client 304 communicatively connected to deployment system 306, for example, through a command line interface (CLI) or other user interface of administrative client 304. In addition to transmitting one or more commands issued by system administrator 302, administrative client 304 may further transmit a bundle of application data, configuration files, and other information (collectively referred to as a “release”), which are unpacked, processed, and/or distributed by deployment system 306 to deploy cloud computing platform application 200, as described later. In addition to the release, administrative client 304 provides a deployment manifest, associated with the release, that describes a desired computing environment of cloud computing platform application 200 after cloud computing platform application 200 has been deployed. The deployment manifest describes attributes of the desired computing environment such as a number of resource pools (e.g., groups of VMs) to be utilized, networks to be set up, and other settings, as will be described later, and functions as a specification for deployment in this embodiment.

Multi-node application platform 300 includes an infrastructure platform 308 upon which cloud computing platform application 200 is deployed and executed. In the embodiment of FIG. 3, infrastructure platform 308 comprises hardware resources 310, such as servers 312 ₁ to 312 _(N) and one or more storage array networks (SAN), such as SAN 314, which are configured in a manner to provide a virtualization environment 316 that supports execution of a plurality of virtual machines (VMs) across servers 312 ₁ to 312 _(N). As further detailed below, these VMs provide virtual computing resources that support the services and functions carried out by deployment system 306, as well as, virtual computing resources for hosting functional components of the cloud computing platform application 200. In one embodiment, infrastructure platform 308 may be implemented as cloud infrastructure services or other Infrastructure-as-a-Service (“IaaS”) that provide computer infrastructure as a service.

Virtualization environment 316 includes an orchestration component 318 (e.g., implemented as a process running in a virtual machine in one embodiment) that monitors the infrastructure resource consumption levels and requirements of deployment system 306 (e.g., by monitoring communications routed through addressing and discovery layer 334 as further detailed below) and provides additional infrastructure resources to deployment system 306 as needed or desired. For example, if deployment system 306 requires additional VMs to host newly deployed functional components of cloud computing platform application 200 and scale the currently running multi-node application to support peak demands, orchestration component 318 can initiate and manage the instantiation of virtual machines on servers 312 ₁ to 312 _(N) to support such needs. In one example implementation of an embodiment similar to that of FIG. 3, virtualization environment 316 may be implemented by running VMware ESX™ based hypervisor technologies on servers 312 ₁ to 312 _(N) provided by VMware, Inc. of Palo Alto, Calif. (although it should be recognized that any other virtualization technologies, including Xen® and Microsoft Hyper-V virtualization technologies may be utilized consistent with the teachings herein).

In the embodiment of FIG. 3, deployment system 306 includes a deployment director 320 (e.g., running in one or more VMs) that orchestrates the deployment process for cloud computing platform application 200 according to a deployment manifest that has been submitted to deployment system 306. Deployment director 320 receives instructions of the deployment manifest and interacts with other components of deployment system 306 to generate a logical infrastructure 350 onto which cloud computing platform application 200 is to be deployed. In the embodiment depicted in FIG. 3, deployment director 320 exposes a communications interface, such as a Representative State Transfer (REST) architecture, through which deployment director 320 receives administrative commands and other deployment data (e.g., a release) from a client (e.g., administrative client 304).

Deployment director 320 may provision VMs (identified as stem cell VMs 324 ₁ to 324 _(M)) to host functional components of cloud computing platform application 200, such as cloud controller 202, application execution agents 206, health manager 208, router, 204, service provisioner 210, etc. In the embodiment of FIG. 3, deployment director 320 request infrastructure platform 308 to dynamically create and delete stem cell VMs (e.g., stem cell VMs 324 ₁ to 324 _(M)). Stem cell VMs 324 ₁ to 324 _(M) are VMs created based on a pre-defined VM template (referred to as “stem cell”) that includes a base operating system, an agent 322, and supporting libraries, runtimes, and/or applications. Agents 322 coordinate with deployment director 320 to configure stem cell VMs 324 ₁ to 324 _(M) to perform various roles of cloud computing platform application 200. Agents 322 applies a particular job to a stem cell VM 324 ₁ executing thereon such that stem cell VM 324 ₁ performs a particular management role within cloud computing platform application 200 (e.g., the job of one of cloud controller 202, health manager 208, application execution agents 206, etc.).

In addition to provisioning stem cell VMs, deployment director 320 may request infrastructure platform 308 to dynamically create and delete temporary VMs, referred to as workers 330, which perform one or more processing tasks that facilitate deployment. In one embodiment, for example, workers 330 may be created to perform software compilation for component applications and/or libraries to be deployed on stem cell VMs 324 ₁ to 324 _(M). Workers 330 are configured with a similar configuration as stem cell VMs 324 ₁ to 324 _(M) (e.g., have an identical virtual hardware specification, architecture, and/or configuration) to enable compiled software to execute on stem cell VMs 324 ₁ to 324 _(M). Results of processing tasks (e.g., software compilation) and other cached data may be stored in an object store 332 (e.g., blob store) used to hold artifacts generated during the deployment process. Further, deployment director 320 may utilize a set of services 328 (e.g., run in one or more VMs) to facilitate orchestration of the deployment process. For example, a relational database service (e.g., MySQL, etc.), monitoring service, background task scheduler, logging service, messaging service, memory object caching service and the like may comprise services 328.

Addressing and discovery layer 334 provides a common interface through which components of deployment system 306, such as deployment director 320, health monitor 336, services 328, workers 330, and one or more agents 322 executing on stem cell VMs 324 ₁ to 324 _(M), can communicate and receive notifications. For example, deployment director 320 may utilize addressing and discovery layer 334 to request the provisioning of VMs from infrastructure platform 308 and to provide agents 322 with deployment instructions during deployment of cloud computing platform application 200. Similarly, stem cell VM 324 ₁ may communicate through addressing and discovery layer 334 with other stem cell VMs 324 _(M) through addressing and discovery layer 334 during deployment of cloud computing platform application 200. In one embodiment, addressing and discovery layer 334 is implemented as a message brokering service (e.g., running in one or more VMs) that defines a common protocol and message format through which components of deployment system 306 can exchange messages and broadcast notifications and other information. In such an embodiment, the components of deployment system 306 establish a connection with the message brokering service (e.g., also sometimes referred to as “subscribing” to the message brokering service), for example, through known authentication techniques (e.g., passwords, etc.) and, once connected to the message brokering service, can provide, receive and request messages, notifications and other similar information to and from other components that have also subscribed to the message brokering system. One example of a message brokering service that may be used in an embodiment is RabbitMQ™ which is based upon the AMPQ (Advanced Message Queuing Protocol) open protocol standard. It should be recognized, however, that alternative interfaces and communication schemes may be implemented for addressing and discovery layer 334 other than such a message brokering service.

Deployment system 306 further comprises a health monitor 336 (e.g., run in a VM) that tracks and maintains the “health” of deployment system 306 by monitoring messages broadcast on addressing and discovery layer 334 by other components of deployment system 306. For example, health monitor 336 may detect a lack of communication from an agent 322 (e.g., run on a stem cell VM) and determine the failure of the stem cell VM (e.g., failure of a component of cloud computing platform application 200). Health monitor 336 may automatically broadcast a request to deployment director 320 to re-start the failed stem cell VM or provision a replacement stem cell VM to perform the same role. Health monitor 336 may be further configured to initiate restart of failed available services or other components of deployment system 306 (e.g., deployment director 320, object store 332, services 328, workers 330, and one or more agents 322 executing on stem cell VMs 324 ₁ to 324 _(M), etc.).

It should be recognized that deployment system architectures other than the embodiment of FIG. 3 may be implemented consistent with the teachings herein. For example, while FIG. 3 implements deployment system 306 on an infrastructure platform 308 hosted by multi-node application platform 300, it should be recognized that deployment system 306 may be implemented by entities other than multi-node application platform 300, on top of any type of hardware infrastructure, such as on a non-virtualized infrastructure platform, as processes or daemons directly on hardware resources 310. It should further be recognized that embodiments may configure deployment system 306 and infrastructure platform 308 in a loosely coupled manner with communication between deployment system 306 and infrastructure platform 308 only occurring through orchestration component 318 of infrastructure platform 308 which monitors hardware resource consumption by connecting to addressing and discovery layer 334). In such loosely coupled embodiments, it should be recognized that deployment system 306 may be implemented on any infrastructure platform, including on a laptop or personal computer (e.g., in which case, each component of deployment system 306 runs as a separate process or daemon on the laptop or personal computer).

FIG. 4 depicts a more detailed view of one embodiment of deployment director 320. Deployment director 320 manages deployment of cloud computing platform application 200 based on a deployment manifest 402 that describes a desired computing environment post-deployment of cloud computing platform application 200. Deployment manifest 402 specifies a release, for example, by name and/or version number, of cloud computing platform application 200 to be deployed. Deployment manifest 402 provides a full specification of cloud computing platform application 200, including specific functional components (e.g., cloud controller 202, health manager 208, application execution agents 206, etc.), a logical infrastructure 350 provided by infrastructure platform 308 (e.g., stem cell VMs 324 _(M)), the functional components' mapping onto logical infrastructure 350. For example, deployment manifest 402 may specify that ten stem cell VMs should be provisioned to host components comprising cloud computing platform application 200. A system administrator may create deployment manifest 402 for an initial deployment of cloud computing platform application 200, modify deployment manifest 402 to scale up or down an already-deployed cloud computing platform application 200, or update a deployed cloud computing platform application 200. In one particular implementation, deployment manifest 402 is a configuration file formatted in a structured document format, such as YAML or eXtensible Markup Language (XML), having name-value pairs and/or hierarchical sections of name-value pairs that facilitate the deployment process by deployment system 306. Details of deployment manifest 402 are described in conjunction with the sample deployment manifest shown in Table 1 below.

TABLE 1 Example Deployment Manifest # Sample Deployment Manifest  name: staging director_uuid: 374d1703-c744-42e5-a773-9299c3fld1a1 release: name: appcloud version: 40 networks: - name: management subnets: - reserved: - 11.23.2.2 - 11.23.2.16 - 11.23.3.238 - 11.23.3.254 static: - 11.23.2.17 - 11.23.2.128 range: 11.23.2.0/23 gateway: 11.23.2.1 dns: - 11.22.22.153 - 11.22.22.154 cloud_properties name: VLAN2002 - name: apps subnets: - reserved: - 11.23.8.2 - 11.23.8.16 - 11.23.15.238 - 11.23.15.254 static: - 11.23.8.17 - 11.23.8.255 - 11.23.9.0 - 11.23.9.255 range: 11.23.8.0/21 gateway: 11.23.8.1 dns: - 11.22.22.153 - 11.22.22.154 cloud_properties: name: VLAN2008 resource_pools: - name: small stemcell: name: bosh-stemcell version: 0.2.39 network: management size: 14 cloud_properties: ram: 1024 disk: 4096 cpu: 1 - name: deas stemcell: name: bosh-stemcell version: 0.2.39 network: apps size: 192 cloud_properties: ram: 16384 disk: 32768 cpu: 4 compilation: network: management cloud_properties: ram: 2048 disk: 4048 cpu: 4 jobs: - name: nats template: nats instances: 1 resource_pool: medium networks: - name: apps static_ips: - 11.23.8.20 - name: cloud_controller template: cloud_controller instances: 8 resource_pool: large canary_watch_time: 30000 update_watch_time: 30000 networks: - name: management default: [dns, gateway] - name: apps - name: router template: router instances: 4 resource_pool: small update: max_in_flight: 2 networks: - name: apps default: [dns, gateway] - name: dmz static_ips: - 11.23.0.16 - 11.23.0.19 - name: health_manager template: health_manager instances: 1 resource_pool: small networks: - name: management - name: apps default: [dns, gateway] - name: dea template: dea instances: 192 resource_pool: deas update: max_in_flight: 12 networks: - name: apps properties: networks: apps: apps management: management nats: user: nats password: 7x09bnVAqw325 address: 11.23.8.20 port: 4222 router: port: 8080 user: b984H8z82KJk3bb8saZNq72 password: ZB398bzmnwm3898b8AQ23

Deployment manifest 402 may specify a network configuration for cloud computing platform application 200 that includes one or more networks and/or virtual local area networks (VLANs). For example, deployment manifest 402 may define one or more network having settings that specify subnets, static or dynamic IP addresses, gateways and DNS addresses, and reserved Internet Protocol (IP) addresses (i.e., IP addresses not to be used by deployment system 306). In the example deployment in Table 1, a first network labeled “management” and a second network labeled “apps” are specified under a section titled “networks.” The network labeled “management” is specified having a static IP address range of 11.23.3.2.17 to 11.23.2.128 with a gateway address of 11.23.2.1 and DNS address of 11.22.22.153. Deployment manifest 402 may specify a “range” of the network that may be used by deployment director 320 as a dynamic pool of IP address, minus static and reserved IP addresses. Gateway and DNS information specified by deployment manifest 402 may be passed onto stem cell VMs and agents 322 executing thereon for their initial launch and bootstrapping. Deployment manifest 402 may include, in each section, one or more pass-through settings (e.g., “cloud_properties”) that will be provided to infrastructure platform 308 during deployment.

Based on deployment manifest 402, deployment director 320 generates a logical infrastructure 350 comprising one or more resource pools (identified as resource pools 404 ₁ and 404 ₂ in FIG. 4) that associate stem cell VMs with a stem cell (e.g., VM template) and a network. For example, a resource pool labeled “small” is associated with a stem cell specified as “bosh-stemcell” version 0.2.39 and with the “management” network defined within deployment manifest 402. A stem cell refers to a VM template that defines a generalized software infrastructure that supports execution of a job provided by deployment director 320 and as specified by deployment manifest 402. In some embodiments, the stem cell is a VM template that includes an agent 322 installed on a guest operating system 406, and any supporting runtimes, frameworks, and libraries for the agent 322. Each resource pool may be assigned a size corresponding to a number of stem cell VMs 324 _(M) to be provisioned for the resource pool. For example, deployment director 320 provisions 14 stem cell VMs for the “small” resource pool. Deployment manifest 402 may include pass-through settings for infrastructure platform 308 for provisioning resource pools 404. For example, the “cloud_properties” section indicates “ram,” “disk,” and “cpu” properties that are intended for use by infrastructure platform 308 in provisioning stem cell VMs (i.e., having 1024 MB of RAM, 4096 Mb of disk space, and 1 CPU) for the “small” resource pool.

Deployment manifest 402 may define a specialized resource pool of workers (e.g., workers 330) for compilation of software packages and/or other ancillary processing tasks during deployment. The specialized resource pool of workers may comprise one or more ancillary VMs provided by infrastructure platform 308. Deployment manifest 402 may specify the number of VMs allocated to the workers resource pool and a network on which compilation may be performed. For example, the “compilation” section above specifies a resource pool having 6 workers assigned to the “management” network for compiling software packages.

Deployment manifest 402 defines a plurality of jobs that may be performed by one or more stem cell VMs 324M as one or more roles in cloud computing platform application 200 (e.g., cloud controller 202, router 204, application execution agents 206, health manager 208, service provisioner 210, services 212, message bus 214, etc.). Deployment manifest 402 specifies a mapping of each job onto logical infrastructure 350 of resource pools 404 and networks specified above. Deployment manifest 402 may specify the number of instances to be deployed of a particular job, which resource pool to use stem cell VMs, and/or which network the job is on. For example, in the example in Table 1, a job labeled as “cloud_controller” is listed as having eight instances (e.g., stem cell VMs 324) drawn from resource pool “large” and assigned to the “management” network. Each job may include a number of configuration file templates, wherein key parameters (e.g., login credentials, IP addresses, ports) are specified as variables.

In one embodiment, deployment manifest 402 includes a “properties” section that provides enables a system administrator to parameterize these configuration file templates. As such, when deployment director 320 deploys cloud computing platform application 200, deployment director 320 may parse the configuration file templates and “fill in” the appropriate parameters based on the corresponding values provided in “properties” section. For example, a router job may have a configuration file that lists a login credential for the router service as variables (“<$user>,” “<$password>”). In such an example, deployment director 320 parses out and evaluates the variables based on “user:” and “password:” name-value pairs provided in the properties section. Table 2 lists an example configuration file template embodied as a Ruby on Rails script file (e.g., ERB template) that may be parsed by deployment director 320.

TABLE 2 Example Configuration File Template external_uri: <%= properties.keys.auth_token %> local_register_only: <%= properties.features.registration %> instanceyort: <%= properties.cloudcontroller.port II 8080%> directories: droplets: <%= data_directory %>/droplets resources: /shared/resources amqp: host: <%= find_job (properties. amqp. job_name, 0) %> port: <%= properties.amqp.port II 5672%> vhost: <%= properties.amqp.vhost %> user: <%= properties.amqp.user %> pass: <%= properties.amqp.password %> log_level: <%= properties.logging.cloudcontroller %> keys: password: <%= properties.keys.password %> token: <%= properties.keys.auth_token %> database_uri: “mysql://<%= find_job properties.mysql.job_name, ) \ %>/db” pid: <%= instance_directory %>/cloudcontroller.pid

FIG. 5 depicts a flow diagram for deploying a cloud computing platform application 200 by deployment director 320. In step 500, deployment director 320 receives a request to deploy cloud computing platform application 200, for example, from administrative client 304. A deployment manifest 402 and release may be included with the request or, in the alternative, may have been previously loaded onto deployment director 320 prior to issuance of the deployment request. As described above, deployment manifest 402 provides a specification of cloud computing platform application 200 that deployment director 320 may use to map management jobs needed for supporting cloud computing platform application 200 to virtual computing resources utilized during deployment. In one embodiment, the release includes one or more application packages and configuration files organized into a tape archive file or a “tar” file (also referred to as a “tarball”). It should be recognized that, rather than transmitting the release itself, alternative embodiments may receive the release in step 500 by receiving a reference to download or otherwise access the release, for example, by providing a reference to object store 332, uniform resource locator (“URL”), Git repository, or other similar reference to package data. In such embodiments, the step of receiving the release would thus utilize the provided reference to fetch the release.

In step 502, deployment director 320 determines a logical infrastructure 350 to host cloud computing platform application 200 based on deployment manifest 402. For example, in one embodiment, deployment director 320 processes deployment manifest 402 to determine an allocation of stem cell VMs organized into resource pools and network groupings for hosting nodes of cloud computing platform application 200. In step 506, deployment director 320 transmits a provision request for a plurality of stem cell VMs, based on logical infrastructure 350 determined in step 502, to infrastructure platform 308, which, in turn, receives the provisioning request in step 506. For example, in one embodiment, deployment director 320 may call for provision of instances of a stem cell VM from a cloud infrastructure service provider utilizing a cloud provider Application Programming Interface, sometimes referred to as a “cloud provider interface” (CPI). In step 508, infrastructure platform 308 creates one or more instances of stem cell VMs utilizing a stem cell template having agent 322 pre-installed and having resource and network configurations as specified by deployment manifest 402. For example, in one embodiment, infrastructure platform 308 may create a stem cell VM utilizing a template (e.g., stem cell) having a packaged format such as Open Virtualization Format (OVF) and containing a guest operating system kernel, utilities (e.g., openssh-server, monit), libraries (e.g., libxml, libmysql, libsqlite), runtime dependencies (e.g., Ruby, Java Virtual Machine), and agent 322. In one particular implementation, the stem cell may be generated prior to start of the deployment procedure and stored for later retrieval by infrastructure platform 308 and/or deployment director 320.

In step 510, one or more stem cell VMs (e.g., stem cell VM 324 ₁) begins operation and launches agent 322. In step 512, deployment director 320 provides job configuration and data to stem cell VMs 324 for each job specified by deployment manifest 402 via addressing and discovery layer 334. For example, deployment director 320 determines that deployment manifest 402 specifies a “cloud controller” job uses eight instances of stem cell VMs drawn from a pre-determined resource pool and from a pre-determined network group. Deployment director 320 provides job configuration and data for the cloud controller job to eight instances of stem cell VMs 324. In step 514, stem cell VMs 324 (e.g., stem cell VM 324 ₁) receives the job configuration and data, via address and discovery layer 334. Job configuration and data may include one or more packaged applications, libraries, runtimes, configuration files, metadata, and other supporting data for performing a role within cloud computing platform application 200. In one embodiment, agent 322 may retrieve job configuration and data utilizing a link or address provided by deployment director 320 and corresponding to one or more data objects stored in object store 332. In step 516, agent 322 applies the received job configuration and data to transform stem cell VM 324 ₁ into a distributed node within cloud computing platform application 200. Agent 322 installs one or more application packages of the received job data, utilizes the received job configuration to perform any suitable setup and configuration of the installed software packages, and launches processes for connecting to other deployed jobs of cloud computing platform application 200 and performing one or more specialized tasks within cloud computing platform application 200. For example, in one embodiment, agent 322 may install, configure, and launch one or more application packages for executing a router (e.g., router 204) to forward incoming requests to other components of cloud computing platform application 200 that are running web applications. Deployment director 320 repeats operations of step 512 until all jobs have been deployed onto one or more stem cell VMs 324 as specified by deployment manifest 402. As such, after the deployment procedure has been completed, a plurality of stem cell VMs have transformed into a plurality of interconnected nodes that constitute a deployed cloud computing platform application 200 (e.g., cloud controller 202, application execution agents 206, health manager 208, router, 204, service provisioner 210, etc.), as depicted in FIG. 6.

FIG. 6 depicts deployment system 306 of FIG. 4 after deployment of a cloud computing platform application 200 has been completed. After execution of a deployment procedure described above, stem cell VMs (e.g., VMs 324 ₁ to 324 _(M)) from logical infrastructure 350 are “transformed” into nodes of a cloud computing platform application 200 (e.g., router 204, cloud controller 202, health manager 208, application execution agents 206, service provisioner 210, services 212, message bus 214). In the embodiment of FIG. 6, each stem cell VM 324 ₁ to 324 _(M) has an agent 322 executing thereon to perform a management job (e.g., router job 604, cloud controller job 602, health manager job 608, application execution agent jobs 606, service provisioner job 610, service jobs 612, message bus job 614) that are carried out by cloud computing platform application 200.

It should be recognized that various modifications and changes may be made to the specific embodiments described herein without departing from the broader spirit and scope of the invention as set forth in the appended claims. For example, while the foregoing description has discussed embodiments of a distributed cloud computing platform application, it should be recognized that any network utilizing application can leverage the techniques disclosed herein, and as such, “cloud computing platform application” as used herein shall be interpreted to include any type of multi-node distributed application that employs network based communications. Furthermore, although the foregoing embodiments have focused on the use of stem cell VMs to host deployed jobs, it should be recognized that any “application container” may be used to host deployed jobs, including such stem cell VMs, processes in virtual machines, kernel level containers, processes in traditional non-virtualized operating systems and any other execution environment that provides an isolated environment capable of running application level code. Similarly, while the various components of deployment system 306 have been generally described as being implemented in one or more virtual machines (e.g., for load balancing and scalability purposes), it should be recognized that any type of “application container” (as previously discussed above) can also implement such components, including, for example, traditional non-virtualized computing environment background processes, threads or daemons. Furthermore, any combination of different types of “application containers” to host deployed jobs and implement other components (e.g., deployment director 320, health monitor 336, services 328, object store 332, workers 330, addressing and discovery layer 334, etc.) can comprise any particular deployment system 306 implementation. It should further be recognized that multiple instances of the various components of deployment system 306 (e.g., deployment director 320, health monitor 336, services 328, workers 330, object store 332, etc.) may be implemented in alternative embodiments, for example, for scalability purposes.

The various embodiments described herein may employ various computer-implemented operations involving data stored in computer systems. For example, these operations may require physical manipulation of physical quantities usually, though not necessarily, these quantities may take the form of electrical or magnetic signals where they, or representations of them, are capable of being stored, transferred, combined, compared, or otherwise manipulated. Further, such manipulations are often referred to in terms, such as producing, identifying, determining, or comparing. Any operations described herein that form part of one or more embodiments of the invention may be useful machine operations. In addition, one or more embodiments of the invention also relate to a device or an apparatus for performing these operations. The apparatus may be specially constructed for specific required purposes, or it may be a general purpose computer selectively activated or configured by a computer program stored in the computer. In particular, various general purpose machines may be used with computer programs written in accordance with the teachings herein, or it may be more convenient to construct a more specialized apparatus to perform the required operations.

The various embodiments described herein may be practiced with other computer system configurations including hand-held devices, microprocessor systems, microprocessor-based or programmable consumer electronics, minicomputers, mainframe computers, and the like.

One or more embodiments of the present invention may be implemented as one or more computer programs or as one or more computer program modules embodied in one or more computer readable media. The term computer readable medium refers to any data storage device that can store data which can thereafter be input to a computer system computer readable media may be based on any existing or subsequently developed technology for embodying computer programs in a manner that enables them to be read by a computer. Examples of a computer readable medium include a hard drive, network attached storage (NAS), read-only memory, random-access memory (e.g., a flash memory device), a CD (Compact Discs) CD-ROM, a CD-R, or a CD-RW, a DVD (Digital Versatile Disc), a magnetic tape, and other optical and non-optical data storage devices. The computer readable medium can also be distributed over a network coupled computer system so that the computer readable code is stored and executed in a distributed fashion.

Although one or more embodiments of the present invention have been described in some detail for clarity of understanding, it will be apparent that certain changes and modifications may be made within the scope of the claims. Accordingly, the described embodiments are to be considered as illustrative and not restrictive, and the scope of the claims is not to be limited to details given herein, but may be modified within the scope and equivalents of the claims. In the claims, elements and/or steps do not imply any particular order of operation, unless explicitly stated in the claims.

Plural instances may be provided for components, operations or structures described herein as a single instance. Finally, boundaries between various components, operations and data stores are somewhat arbitrary, and particular operations are illustrated in the context of specific illustrative configurations. Other allocations of functionality are envisioned and may fall within the scope of the invention(s). In general, structures and functionality presented as separate components in exemplary configurations may be implemented as a combined structure or component. Similarly, structures and functionality presented as a single component may be implemented as separate components. These and other variations, modifications, additions, and improvements may fall within the scope of the appended claims(s). 

We claim:
 1. A method for deploying an application having a plurality of functional components that are executed on a plurality of different nodes, the method comprising: receiving, by a deployment module, a specification for the application, wherein the specification specifies (i) a number of instances of each functional component of the application that is to be deployed, and (ii) hardware properties that would be required by any node executing any one of the functional components; requesting a virtual infrastructure platform to launch a plurality of virtual machines (VMs) that is sufficient to execute each instance of a functional component in a separate VM, wherein each of the VMs (i) is configured to support hardware properties required by at least one of the functional components, and (ii) includes an agent component configured to communicate with the deployment module; requesting the virtual infrastructure platform to launch a plurality of ancillary virtual machines according to a number of ancillary virtual machines specified by the specification, wherein each of the ancillary virtual machines in the plurality of ancillary virtual machines corresponds to at least one of the functional components and is configured to enable compilation of software to be executed by the corresponding functional component; directing at least one of the ancillary virtual machines to compile machine architecture independent code into code executable by each of the VMs to execute as one of the instances of the functional components of the application; and directing each of the agent components in each of the VMs to install the code compiled by the at least one ancillary virtual machine in the VM that implements one of the functional components that is compatible with the hardware properties of the VM, thereby causing the VM to execute as one of the instances of the functional components of the application.
 2. The method of claim 1, wherein the directing each of the agent components to install code further comprises: directing each of the agent components in each of the VMs to install a package of computer-executable instructions specified by the specification for each functional component, and configured to, when executed by each VM, perform operations of the functional component.
 3. The method of claim 1, wherein the specification for the application to be deployed specifies network properties that would be required by any node executing any one of the functional components; and wherein each of the VMs is configured according to the network properties required by at least one of the functional components.
 4. The method of claim 1, wherein the specification specifies a plurality of configuration settings for any one of the functional components; and wherein directing each of the agent components to install code further comprises: retrieving a configuration file for one of the functional components, wherein the configuration file specifies at least one configuration setting having a variable that references one of the plurality of configuration settings in the specification; modifying the configuration file to replace the variable with a value of the referenced configuration setting provided by the specification; and providing the modified configuration file to each of the agent components in each of the VMs that host an instance of the functional component corresponding to the modified configuration file.
 5. The method of claim 1, wherein the requesting the virtual infrastructure platform to launch the plurality of VMs further comprises: requesting provision of each of the VMs using a template that specifies a disk image having a guest operating system and the agent component installed thereon.
 6. The method of claim 1, wherein the plurality of functional components for the application are configured to coordinate to provide cloud computing services to host one or more web applications.
 7. A non-transitory computer-readable storage medium comprising instructions that, when executed in a computing device, deploy an application having a plurality of functional components that are executed on a plurality of different nodes, by performing the steps of: receiving, by a deployment module, a specification for the application, wherein the specification specifies (i) a number of instances of each functional component of the application that is to be deployed, and (ii) hardware properties that would be required by any node executing any one of the functional components; requesting a virtual infrastructure platform to launch a plurality of virtual machines (VMs) that is sufficient to execute each instance of a functional component in a separate VM, wherein each of the VMs (i) is configured to support hardware properties required by at least one of the functional components, and (ii) includes an agent component configured to communicate with the deployment module; requesting the virtual infrastructure platform to launch a plurality of ancillary virtual machines according to a number of ancillary virtual machines specified by the specification, wherein each of the ancillary virtual machines in the plurality of ancillary virtual machines corresponds to at least one of the functional components and is configured to enable compilation of software to be executed by the corresponding functional component; directing at least one of the ancillary virtual machines to compile machine architecture independent code into code executable by each of the VMs to execute as one of the instances of the functional components of the application; and directing each of the agent components in each of the VMs to install the code compiled by the at least one ancillary virtual machine in the VM that implements one of the functional components that is compatible with the hardware properties of the VM, thereby causing the VM to execute as one of the instances of the functional components of the application.
 8. The non-transitory computer-readable storage medium of claim 7, wherein the instructions for directing each of the agent components to install code further comprise instructions for: directing each of the agent components in each of the VMs to install a package of computer-executable instructions specified by the specification for each functional component, and configured to, when executed by each VM, perform operations of the functional component.
 9. The non-transitory computer-readable storage medium of claim 7, wherein the specification for the application to be deployed specifies network properties that would be required by any node executing any one of the functional components; and wherein each of the VMs is configured according to the network properties required by at least one of the functional components.
 10. The non-transitory computer-readable storage medium of claim 7, wherein the specification specifies a plurality of configuration settings for any one of the functional components; and wherein the instructions for directing each of the agent components to install code further comprise instructions for: retrieving a configuration file for one of the functional components, wherein the configuration file specifies at least one configuration setting having a variable that references one of the plurality of configuration settings in the specification; modifying the configuration file to replace the variable with a value of the referenced configuration setting provided by the specification; and providing the modified configuration file to each of the agent components in each of the VMs that host an instance of the functional component corresponding to the modified configuration file.
 11. The non-transitory computer-readable storage medium of claim 7, wherein the instructions for requesting the virtual infrastructure platform to launch the plurality of VMs further comprising instructions for: requesting provision of each of the VMs using a template that specifies a disk image having a guest operating system and the agent component installed thereon.
 12. The non-transitory computer-readable storage medium of claim 7, wherein the plurality of functional components for the application are configured to coordinate to provide cloud computing services to host one or more web applications.
 13. A computer system for deploying an application having a plurality of functional components that are executed on a plurality of different nodes, the computer system comprising a system memory and a processor programmed to carry out the steps of: receiving, by a deployment module, a specification for the application, wherein the specification specifies (i) a number of instances of each functional component of the application that is to be deployed, and (ii) hardware properties that would be required by any node executing any one of the functional components; requesting a virtual infrastructure platform to launch a plurality of virtual machines (VMs) that is sufficient to execute each instance of a functional component in a separate VM, wherein each of the VMs (i) is configured to support hardware properties required by at least one of the functional components, and (ii) includes an agent component configured to communicate with the deployment module; requesting the virtual infrastructure platform to launch a plurality of ancillary virtual machines according to a number of ancillary virtual machines specified by the specification, wherein each of the ancillary virtual machines in the plurality of ancillary virtual machines corresponds to at least one of the functional components and is configured to enable compilation of software to be executed by the corresponding functional component; directing at least one of the ancillary virtual machines to compile machine architecture independent code into code executable by each of the VMs to execute as one of the instances of the functional components of the application; and directing each of the agent components in each of the VMs to install the code compiled by the at least one ancillary virtual machine in the VM that implements one of the functional components that is compatible with the hardware properties of the VM, thereby causing the VM to execute as one of the instances of the functional components of the application.
 14. The computer system of claim 13, wherein the processor is further programmed to carry out the step of: directing each of the agent components in each of the VMs to install a package of computer-executable instructions specified by the specification for each functional component, and configured to, when executed by each VM, perform operations of the functional component.
 15. The computer system of claim 13, wherein the specification for the application to be deployed specifies network properties that would be required by any node executing any one of the functional components; and wherein each of the VMs is configured according to the network properties required by at least one of the functional components.
 16. The computer system of claim 13, wherein the specification specifies a plurality of configuration settings for any one of the functional components; and wherein the processor is further programmed to carry out the step of: retrieving a configuration file for one of the functional components, wherein the configuration file specifies at least one configuration setting having a variable that references one of the plurality of configuration settings in the specification; modifying the configuration file to replace the variable with a value of the referenced configuration setting provided by the specification; and providing the modified configuration file to each of the agent components in each of the VMs that host an instance of the functional component corresponding to the modified configuration file.
 17. The computer system of claim 13, wherein the plurality of functional components for the application are configured to coordinate to provide cloud computing services to host one or more web applications.
 18. The method of claim 1, wherein the deployment module further comprises a health monitor configured to: monitor communications from agents running on VMs launched by the virtual infrastructure platform; and re-start a failed VM if a lack of communication from the VM is detected.
 19. The non-transitory computer-readable storage medium of claim 7, wherein the deployment module further comprises a health monitor configured to: monitor communications from agents running on VMs launched by the virtual infrastructure platform; and re-start a failed VM if a lack of communication from the VM is detected.
 20. The computer system of claim 13, wherein the deployment module further comprises a health monitor configured to: monitor communications from agents running on VMs launched by the virtual infrastructure platform; and re-start a failed VM if a lack of communication from the VM is detected.
 21. The method of claim 1, wherein ancillary virtual machines within the plurality of ancillary virtual machines are configured with a virtual hardware specification and architecture that is identical to the functional component.
 22. The non-transitory computer-readable storage medium of claim 7, wherein ancillary virtual machines within the plurality of ancillary virtual machines are configured with a virtual hardware specification and architecture that is identical to the functional component.
 23. The computer system of claim 13, wherein ancillary virtual machines within the plurality of ancillary virtual machines are configured with a virtual hardware specification and architecture that is identical to the functional component. 